Low-energy M1 states in deformed nuclei: spin-scissors or spin-flip?

Abstract

The low-energy M1 states in deformed 164Dy and spherical 58Ni are explored in the framework of fully self-consistent Quasiparticle Random-Phase Approximation (QRPA) with various Skyrme forces. The main attention is paid to orbital and spin M1 excitations. The obtained results are compared with the prediction of the low-energy spin-scissors M1 resonance suggested within Wigner Function Moments (WFM) approach. A possible relation of this resonance to low-energy spin-flip excitations is analyzed. In connection with recent WFM studies, we consider evolution of the low-energy spin-flip states in 164Dy with deformation (from the equilibrium value to the spherical limit). The effect of tensor forces is briefly discussed. It is shown that two groups of 1+ states observed at 2.4-4 MeV in 164Dy are rather explained by fragmentation of the orbital M1 strength than by the occurrence of the collective spin-scissors resonance. In general, our calculations do not confirm the existence of this resonance.